Optical communication for body mountable devices

ABSTRACT

A system includes one or more optical emitters, a transceiver, and a body mountable device. The optical emitters emit light and are configured to be used in luminaires. The transceiver is coupled to receive input data from a data network and coupled to selectively modulate the optical emitters to transmit the optical data. Selectively modulating the optical emitters is in response to the input data. The body mountable device includes a photodetector coupled to receive the optical data and processing circuitry configured to initiate an action in response to receiving the optical data from the photodetector.

TECHNICAL FIELD

This disclosure relates generally to mobile communications, and inparticular but not exclusively, relates to optical communications forbody mountable devices.

BACKGROUND INFORMATION

Body mountable devices including “wearables” have increased in usabilityas computing resources, batteries, and peripheral electronics becomesmaller and more efficient. Wearable technology has applications in headmounted display (“HMDs”), patches, arm bands, watches, integration intoclothing, and otherwise. Wearables often are specifically designed for aspecific task or measurement. Since wearables sometimes have limiteduser interface features, they may require prompting from another deviceto perform their task or measurement. Other devices (e.g. smart phones,tablets, computers) may have more accessible or convenient userinterfaces to initiate a task or measurement that the wearable willperform. After performing a given task, the wearable may be bestutilized by reporting the measurement to another device for furtheranalysis or viewing. Therefore, communications systems on body mountabledevices can increase the functionality of the body mountable device.Given the often small constraints with body mountable devices, theircommunication systems often have to be designed within the form factorlimitations of the device involved. Communication systems havingincreased accessibility in addition to being small, light, and efficientwould be advantageous to reduce form factors and increase use cases andintegration into different body mountable devices.

BRIEF DESCRIPTION OF THE DRAWINGS

Non-limiting and non-exhaustive embodiments of the invention aredescribed with reference to the following figures, wherein likereference numerals refer to like parts throughout the various viewsunless otherwise specified.

FIG. 1 illustrates an example system diagram that includes a network, atransceiver, optical emitters, and a body mountable device, inaccordance with an embodiment of the disclosure.

FIG. 2A illustrates a block diagram of an example body mountable devicethat includes processing circuitry, a photodetector, and emitters, inaccordance with an embodiment of the disclosure.

FIG. 2B illustrates an example configuration of processing circuitry fordriving an LED in both a detector and emitter mode, in accordance withan embodiment of the disclosure.

FIG. 3A illustrates a top view of a smart contact lens that includesprocessing circuitry, a notification emitter, and an outward facingemitter, in accordance with an embodiment of the disclosure.

FIG. 3B illustrates a side view of a smart contact lens that includesprocessing circuitry, a notification emitter, and an outward facingemitter, in accordance with an embodiment of the disclosure.

FIG. 3C illustrates a cross-section side view of an example smartcontact lens mounted on a corneal surface of an eye, in accordance withan embodiment of the disclosure.

FIG. 3D illustrates a zoomed-in view of a notification emitter includedin FIG. 3C, in accordance with an embodiment of the disclosure.

FIG. 3E illustrates a zoomed-in view of an outward facing emitterincluded in FIG. 3C, in accordance with an embodiment of the disclosure.

FIG. 4 includes a flow chart showing a process of generatingnotifications for a smart contact lens, in accordance with an embodimentof the disclosure.

DETAILED DESCRIPTION

Embodiments of a system and method for optical communication for bodymountable devices are described herein. In the following description,numerous specific details are set forth to provide a thoroughunderstanding of the embodiments. One skilled in the relevant art willrecognize, however, that the techniques described herein can bepracticed without one or more of the specific details, or with othermethods, components, materials, etc. In other instances, well-knownstructures, materials, or operations are not shown or described indetail to avoid obscuring certain aspects.

Reference throughout this specification to “one embodiment” or “anembodiment” means that a particular feature, structure, orcharacteristic described in connection with the embodiment is includedin at least one embodiment of the present invention. Thus, theappearances of the phrases “in one embodiment” or “in an embodiment” invarious places throughout this specification are not necessarily allreferring to the same embodiment. Furthermore, the particular features,structures, or characteristics may be combined in any suitable manner inone or more embodiments.

FIG. 1 illustrates an example system diagram that includes a mobiledevice 190, a network 180, a transceiver 170, a photodetector 160,optical emitters 150, and a body mountable device 110, in accordancewith an embodiment of the disclosure. Network 180 may include switchesand other routing circuitry. Network 180 may include wired and wirelessaccess points. Mobile device 190 can access network 180 via networkconnection 115. Mobile device 190 may be a smartphone, tablet, a smartwatch, or other network connectable device that includes a userinterface for user input. Network connection 115 may be provided viaintermediate networks (e.g. wireless provider network) that areunillustrated for simplicity. In one example network 180 is a privatenetwork that has wired and wireless access points in a given buildingstructure. Mobile device 190 may access network 180 directly byconnecting to a wireless access point or mobile device 190 may accessnetwork 180 indirectly by first connecting to a wireless provider thatthen accesses network 180.

Transceiver 170 can access network 180 via network connection 117, whichmay be a direct connection (via wired or wireless access points) tonetwork 180 or an indirect connection (via another network such as awireless network). Transceiver 170 is coupled to receive input data fromnetwork 180 via network connection 117. Transceiver 170 is also coupledto one or more optical emitters 150 which emit light. The light emittedby optical emitters 150 may be visible or non-visible. Transceiver 170is coupled to selectively modulate the one or more optical emitters 150in response to the input data received from network 180 to transmitoptical data 155 via the light emitted from the optical emitters.

In one embodiment, optical emitters 150 are light-emitting-diodes(“LEDs). Optical emitters 150 may be configured for use in a luminaire143. Optical emitters 150 may be designed to have a form factor that areeasily installed into legacy luminaire light fixtures or opticalemitters 150 may be integrated into a luminaire light fixture. Forexample, optical emitters 150 may be configured to screw into commonexisting sockets that receive conventional incandescent light bulbs orfluorescent light bulbs. For the purposes of this disclosure,“luminaire” is defined as a light fixture for illuminating a space (e.g.commercial space or residential space). Luminaires may also be used toilluminate outdoor space such as streets, parks, or outdoor venues. Aluminaire includes a power input to receive electrical power to powerits light emitters that emit ambient light for the space. Luminairescommonly include reflectors to direct ambient light from light emitters(e.g. light bulbs) in the desired direction, although this may be lessimportant when LEDs are the light emitters. Luminaires exist forceiling, wall-mount, street light, and portable (e.g. desk lamp or floorlamp) applications.

Optical emitters 150, photodetector 160, and transceiver 170 may beincluded in a mobile device such as a smartphone, tablet, or a headmounted display (“HMD”). Optical emitters 150, photodetector 160, andtransceiver 170 may also be included in a television, a settop box, or acomputer, or otherwise. The display screens or LEDs on these devices mayserve as optical emitters 150 and be modulated (at a frequency abovewhat the human eye can discern) to include optical data. Image sensorson these devices may serve as photodetector(s) 160. All of these devicescommonly have access to the internet and other private data networkscapable of sending and receiving data.

Body mountable device 110 includes a photodetector (not illustrated) toreceive optical data 155. Body mountable device 110 also includesprocessing circuitry (not illustrated) that is coupled to thephotodetector and the processing circuitry is coupled to initiate anaction in response to receiving optical data 155. In some embodiments,body mountable device 110 includes an outward facing emitter that emitsdevice light. In those embodiments, the processing circuitry is coupledto selectively drive/modulate the outward facing emitter to generatedevice data 165. The outward facing emitter may emit non-visible (e.g.infrared light).

Transceiver 170 is coupled to photodetector(s) 160 to receive devicedata 165 and coupled to send device data to network 180 via networkconnection 117. Photodetector(s) 160 may be optionally mounted toluminaire 143. Transceiver 170 may also be mounted to or integrated intoluminaire 143.

Body mountable device 110 may include devices worn on or about the body.Body mountable devices include wearables such as HMDs, patches, armbands, watches, pedometers, wearables integrated into clothing, andotherwise. Body mountable devices may include implantable devices thatare implanted just under skin. Body mountable devices are used by peopleand people tend to congregate around facilities and infrastructure thatincludes lighting. Therefore, a communication system that utilizesexisting infrastructures (e.g. luminaires) and/or common requirementsfor buildings and structures has particular relevance to body mountabledevices. Furthermore, as body mountable devices become smaller andsmaller, the device space available to integrate antennas for radiocommunications may become scarce. Consequently, optical communicationsthat require less device space than radio communication is increasinglyattractive. In addition to utilizing common building infrastructure(e.g. luminaires), other existing “ambient” devices (e.g. televisions,computers, mobile devices, settop boxes) that are commonly available canbe leveraged to provide data to body mountable device 110.

FIG. 2A illustrates an example body mountable device 210 that includesprocessing circuitry 205, a photodetector 220, an outward facing emitter230, a notification emitter 235, a memory 206, and a sensor 245, inaccordance with an embodiment of the disclosure. Body mountable device210 also includes a power source (not illustrated) to power theillustrated elements. The power source may include a battery and/or aphotovoltaic element that generates electrical power by harvestinglight.

Processing circuitry 205 may include a combination of analog and/ordigital circuitry. In FIG. 2A, processing circuitry 205 is illustratedas a microprocessor. Processing circuitry 205 is coupled to read andwrite memory 206. Memory 206 may store instructions for execution onprocessing circuitry 205. Processing circuitry 205 is coupled toinitiate a measurement or test by sensor 245. Sensor 245 is coupled tosend the measurement or the results of the test to processing circuitry205. Sensor 245 may measure biometric data. In one embodiment, sensor245 is a militarized glucose meter. In one embodiment, sensor 245measures biometrics that are representative of a blood alcohol level ofa wearer of body mountable device 210.

Photodetector 220 is positioned to receive optical data 155.Photodetector 220 includes a photodiode, in one embodiment. Processingcircuitry 205 is coupled to read an output of photodetector 220 andanalyze optical data 155. After analyzing optical data 155, processingcircuitry 205 may initiate an action in response to optical data 155.For example, optical data 155 may be a digital word that instructsprocessing circuitry to initiate a measurement using sensor 245.

Body mountable device 210 may include an outward facing emitter 230 tofacilitate outbound communication. For example, outward facing emitter230 can be driven/modulated by processing circuitry 205 to send devicedata 165 via light emitted by outward facing emitter 230. Outward facingemitter 230 may send non-visible light (e.g. infrared) signals thatinclude device data 165. Outward facing emitter 230 may also emitvisible light.

Body mountable device 210 may include notification emitter 235 that isdifferent from outward facing emitter 230. Notification emitter 235 maybe an LED or plurality of LEDs that emit visible light to serve as avisual notification for a wearer of body mountable device 210, whereasoutward facing emitter 230 may be an LED that emits non-visible light.Notification emitter 235 may include more than one LED that emitdifferent colors of light (e.g. red/green/blue). Different colored LEDswithin notification emitter 235 may be selectively driven to generate avariable spectrum of visible light by mixing the different emissioncolors. Notification emitter 235 may include a pixel matrix ofmulti-color LEDs and corresponding driving transistors that form a microdisplay for notifying a wearer of body mountable device 210. In oneembodiment, notification emitter 235 also serves as outward facingemitter 230 by directing at least a portion of the notification lightfrom notification emitter 235 outward for detection by photodetector160.

FIG. 2B illustrates an example configuration of processing circuitry 205for driving an LED 217 in both a detector and emitter mode, inaccordance with an embodiment of the disclosure. Since device space maybe at an especially high premium on body mountable device 210, FIG. 2Billustrates a configuration that utilizes LED 217 in a dual purpose roleas both detector 220 and as emitter 235 or 230.

To drive LED 217 to emit light (emitter mode), pin 207 is driven highwhich yields a voltage (e.g. 2.5V) on pin 207. At the same time, pin 208is driven low (or set to ground) which generates a positive voltageacross LED 217 and resistor R1 218 that causes LED 217 to emit light. Indetector mode, LED 217 is sensitive to light at and above the wavelengththat the LED 217 emits. Therefore, optical data 155 must be sent withlight that is compatible to be sensed by LED 217. To begin detectormode, pin 208 is driven high (e.g. 2.5 VDC) while pin 207 is grounded.This reverse biases LED 217 and charges the capacitance of LED 217. Ofcourse, those skilled in the art understand that diodes include acapacitance inherent in the p-n junction of the diode. After reversebiasing LED 217, pin 208 is set as an input pin which allows thephotocurrent of LED 217 to discharge the capacitance of LED 217. Anincreased intensity of light incident on LED 217 increases thephotocurrent generated by LED 217. As the photocurrent discharges thecapacitance of LED 217, the voltage on pin 208 decreases. Therefore,measuring the time it takes for the capacitance of LED 217 to bedischarged will be representative of the intensity of light on LED 217.The digital input threshold (e.g. 1.25 VDC) of pin 208 is a convenientthreshold that can be used to determine the end time of the dischargingof the capacitance of LED 217. Hence, the time it takes for LED 217 todischarge from a digital high voltage (e.g. 2.5V) to the digital inputthreshold of pin 208 can be conveniently used to measure the intensityof light on LED 217. This detector mode process can be repeated over andover to sense optical data included in light from optical emitters 150.

FIG. 3A illustrates a top view of a smart contact lens (“SCL”) 310 thatincludes processing circuitry 205, notification emitter 235, and anoutward facing emitter 230, in accordance with an embodiment of thedisclosure. SCL 310 is one example of a body wearable device 210.Although not illustrated, SCL 310 may include every element shown inFIG. 2A. SCL 310 includes transparent material 320 that is made from abiocompatible material suitable for a contact lens. Substrate 330 isillustrated as a substantially flattened ring disposed atop or embeddedwithin transparent material 320. In one embodiment, the flattened ringhas a diameter of about 10 millimeters, a radial width of about 1millimeter, and a thickness of about 50 micrometers.

Substrate 330 includes one or more surfaces for mounting the elementsillustrated in FIG. 2A, although only processing circuitry 205,notification emitter 235, and an outward facing emitter 230 areillustrated in FIG. 3A. The different elements may be disposed on bothsides of substrate 330. In one embodiment, substrate 330 includes amulti-layer circuit board. In one embodiment, substrate 330 is made of arigid material such as polyethylene terephthalate (“PET”). In oneembodiment, substrate 330 is made of flexible material such as polyimideor organic material. Substrate 330 may be disposed along an outerperimeter of SCL 310 so as not to interfere with a viewable region ofSCL 310 that a wearer of SCL 310 would be looking through. However, inone embodiment, substrate 330 is substantially transparent and does notsubstantially interfere with a wearer's view, regardless of dispositionlocation.

FIG. 3B illustrates a side view of a SCL 310 that includes processingcircuitry 205, notification emitter 235, and an outward facing emitter230, in accordance with an embodiment of the disclosure. FIG. 3B showstransparent material 320 has a concave surface side 326 opposite aconvex surface side 324. Concave surface side 326 will have substantialcontact with the eye of a wearer of SCL 310. A circular outside edge 328connects concave surface side 326 and convex surface side 324.

FIG. 3B shows that outward facing emitter 230 is positioned to emit lenslight 363 that includes lens data 365 in an outward facing direction sothat it can be received by photodetector(s) 160. In contrast,notification emitter 235 is positioned to emit notification light 339 inan eyeward direction so that the wearer of SCL 310 would be able to seenotification light 339. The eyeward direction may be toward a pupil of awearer of SCL 310 or the eyeward direction may be across SCL 310 and berefracted or reflected into the pupil. An additional notificationemitter (not illustrated) may be disposed in a different location onsubstrate 330 than notification emitter 235 to provide notificationlight to a different viewable region than notification emitter 235. SCL310 may be weighted using similar techniques as contacts that aredesigned for astigmatisms to keep notification emitter 235 in aconsistent location (e.g. upper right hand corner of eye) so thatnotification light 339 is emitted from a consistent position.

FIG. 3C illustrates a cross-section side view of an example SCL 310mounted on a corneal surface 20 of an eye 10, in accordance with anembodiment of the disclosure. SCL 310 is shown mounted under uppereyelid 30 and lower eyelid 32. FIG. 3D illustrates a zoomed-in view ofthe notification emitter 235 included in FIG. 3C, in accordance with anembodiment of the disclosure. Notification emitter 235 is disposed on acornea facing side of substrate 330 so that it can emit notificationlight 339 in an eyeward direction. FIG. 3E illustrates a zoomed-in viewof the outward facing emitter 230 included in FIG. 3C, in accordancewith an embodiment of the disclosure. Outward facing emitter 230 isdisposed on an outward facing side of substrate 330 that is opposite thecornea facing side so that it can send lens data 365 to photodetectors160.

FIG. 4 includes a flow chart showing a process 400 of generatingnotifications for a smart contact lens, in accordance with an embodimentof the disclosure. The order in which some or all of the process blocksappear in process 400 should not be deemed limiting. Rather, one ofordinary skill in the art having the benefit of the present disclosurewill understand that some of the process blocks may be executed in avariety of orders not illustrated, or even in parallel.

In process block 405, input data is sent to a network. In one example,mobile device 190 sends the input data to network 180. Optical emitters(e.g. optical emitters 150) are modulated to broadcast the input data asoptical data (e.g. optical data 155) in process block 410. The opticalemitters are included in or mounted to one or more luminaires.Transceiver 170 may modulate the optical emitters in one embodiment. Theoptical emitters may be LEDs installed in one or more luminaires. In oneembodiment, at least one luminaire in each room of a building or campushas a local transceiver 170 modulating one or more optical emitters 150to broadcast the optical data to an entire building or campus.

In one embodiment, the input data (and corresponding optical data) isencrypted so that only a body mountable device (e.g. SCL 310) with theproper encryption key can decrypt the optical data. The sender (e.g.mobile device 190) of the input data may encrypt the data. The bodymountable device may be previously paired with the sender of the inputdata to coordinate encryption/decryption keys. Memory 206 of bodymountable device 210 may store the decryption key for processingcircuitry 205 to access.

In process block 415, the optical data is received from the opticalemitters of the luminaires by a photodetector (e.g. photodetector 220)of the body mountable device (e.g. SCL 310). The notification emitter(e.g. emitter 235) is activated by processing circuitry 205 in processblock 420. Notification emitter 235 is positioned to emit notificationlight 339 in an eyeward direction, when activated. Notification light339 may be different colors, positions or have different durations,depending on the optical data. The presence or absence of notificationlight 339 may indicate a category of notification or a specificnotification to wearer of an SCL. The flashing frequency, duration,color or combination of colors from different notification emitters mayalso indicate a category of notification or a specific notification.

In one example notifications are used to guide a wearer of SCL 310 to adestination via turn-by-turn directions. A destination could be selectedby a user using a mobile device. Once the destination is selected, themobile device could be pocketed and the visual turn-by-turn directiongiven by notification light from notification emitter(s) in SCL 310. Themobile device may determine a position of the user (using GPS or networktriangulation) and send the position to a remote server. The remoteserver then may send a turn-by-turn direction back to the mobile devicebased on the position sent to the remote server. The mobile device maythen send the turn-by-turn direction to network 180 as input data thatis broadcasted as optical data 155. Notification light can then beemitted by SCL 310 to indicate a direction of travel for the user to getto the desired destination. In one embodiment, green notification lightis a directive to the wearer of SCL 310 to turn left and a bluenotification light is a directive to the wearer of SCO to turn right. Inanother embodiment, a location (e.g. upper left or upper right) of thenotification light indicates direction. Other visual cues (e.g. durationor frequency of notification light) corresponding with a direction orlength of travel to the desired destination can be utilized to directthe wearer of SCL 310 to the destination. One potential advantage ofturn-by-turn directions via SCL 310 is that a user does not have tocontinually view her mobile device to receive turn-by-turn directions.And, because of the possible ubiquity of modulated optical emitters 150inside a building, SCL 310 is always able to receive the optical data155.

In another example, notification light 339 in SCL 310 is used to notifya wearer of SCL 310 of a biometric measurement. A request to initiate abiometric measurement may be made by the wearer of SCL 310 using a userinterface on a mobile device or a computer. A parent, doctor, orcaregiver could also initiate the request. The request would be routedto network 180 via network connection 115 and be delivered totransceiver 170 as input data. The transceiver would broadcast the inputdata as optical data 155 which can be received by photodetector 220.Processing circuitry 205 may be configured to initiate a biometricmeasurement with sensor 245 in response to the optical data. Thebiometric measurement may include a glucose measurement, a blood alcohollevel measurement, or otherwise. Processing circuitry 205 may drive aspecific color of notification emitter based on the results of the test.In one embodiment, a green notification emitter is momentarily activatedto alert a wearer of SCL 310 that the test was negative and a rednotification emitter is momentarily activated to alert a wearer of SCL310 that the test was positive (e.g. glucose level is approaching acertain threshold). The specific results of the test may be stored inmemory 206 for downloading at a later time or the specific results ofthe test may be sent as lens data 365 to photodetector(s) 160 and backto mobile device 190 via network 180.

In another example, notification light 339 in SCL 310 is representativeof a notification corresponding to a mobile application. In oneembodiment, a color of the notification light 339 corresponds to aparticular category of mobile application (e.g. social media, email,calendar). In a final example, public safety announcements (e.g. firealarm, amber alerts) can be routed through network 180, be broadcastedas optical data 155, and utilize notification light 339 to alert wearersof SCL 310 of important information. This notification capability mayhave particular relevance for persons with disabilities, namely hearingimpairments, as many important announcements are auditory.

The processes explained above are described in terms of computersoftware and hardware. The techniques described may constitutemachine-executable instructions embodied within a tangible ornon-transitory machine (e.g., computer) readable storage medium, thatwhen executed by a machine will cause the machine to perform theoperations described. Additionally, the processes may be embodied withinhardware, such as an application specific integrated circuit (“ASIC”) orotherwise.

A tangible non-transitory machine-readable storage medium includes anymechanism that provides (i.e., stores) information in a form accessibleby a machine (e.g., a computer, network device, personal digitalassistant, manufacturing tool, any device with a set of one or moreprocessors, etc.). For example, a machine-readable storage mediumincludes recordable/non-recordable media (e.g., read only memory (ROM),random access memory (RAM), magnetic disk storage media, optical storagemedia, flash memory devices, etc.).

The above description of illustrated embodiments of the invention,including what is described in the Abstract, is not intended to beexhaustive or to limit the invention to the precise forms disclosed.While specific embodiments of, and examples for, the invention aredescribed herein for illustrative purposes, various modifications arepossible within the scope of the invention, as those skilled in therelevant art will recognize.

These modifications can be made to the invention in light of the abovedetailed description. The terms used in the following claims should notbe construed to limit the invention to the specific embodimentsdisclosed in the specification. Rather, the scope of the invention is tobe determined entirely by the following claims, which are to beconstrued in accordance with established doctrines of claiminterpretation.

What is claimed is:
 1. A system comprising: one or more optical emittersthat emit light; a transceiver coupled to receive input data from a datanetwork and coupled to selectively modulate the optical emitters totransmit optical data, wherein selectively modulating the opticalemitters is in response to the input data; and a body mountable devicefor wearing on a human body of a user or implanting into the human bodyof the user, the body mountable device including: a photodetectorcoupled to receive the optical data; and processing circuitry configuredto initiate an action in response to receiving the optical data from thephotodetector, wherein the optical data includes turn-by-turndirections, and wherein the processing circuitry activates anotification emitter to indicate a direction of travel for a wearer ofthe body mountable device.
 2. The system of claim 1, wherein the one ormore optical emitters are configured to be used in luminaires.
 3. Thesystem of claim 1, wherein the body mountable device includes thenotification emitter positioned to emit notification light, wherein theprocessing circuitry is coupled to activate the notification emitter inresponse to the optical data.
 4. The system of claim 1, wherein theoptical data includes a notification corresponding to a mobileapplication, and wherein a color of the notification light correspondswith a particular category of mobile application.
 5. The system of claim1, wherein the processing circuitry is configured to selectively drivethe photodetector as an outward emitter for generating device data. 6.The system of claim 1, wherein the body mountable device includes anoutward facing emitter positioned to emit device data.
 7. A systemcomprising: one or more optical emitters that emit light; a transceivercoupled to receive input data from a data network and coupled toselectively modulate the optical emitters to transmit optical data,wherein selectively modulating the optical emitters is in response tothe input data; and a body mountable device for wearing on a human bodyof a user or implanting into the human body of the user, the bodymountable device including: a photodetector coupled to receive theoptical data; and processing circuitry configured to initiate an actionin response to receiving the optical data from the photodetector,wherein the body mountable device includes a sensor coupled to theprocessing circuitry, wherein the processing circuitry is configured toinitiate a biometric measurement with the sensor in response to theoptical data.
 8. A system comprising: one or more optical emitters thatemit light; a transceiver coupled to receive input data from a datanetwork and coupled to selectively modulate the optical emitters totransmit optical data via the light, wherein selectively modulating theoptical emitters is in response to the input data; and a smart contactlens (“SCL”) including: a photodetector positioned to receive theoptical data; a notification emitter positioned to emit notificationlight in an eyeward direction; and processing circuitry configured toinitiate an action in response to receiving the optical data from thephotodetector, wherein the processing circuitry is coupled to activatethe notification emitter in response to the optical data.
 9. The systemof claim 8, wherein the SCL includes an additional notification emitterpositioned to emit additional notification light in the eyewarddirection, wherein the additional notification emitter emits theadditional notification light having a different color than thenotification light.
 10. The system of claim 8, wherein the optical dataincludes turn-by-turn directions, and wherein the processing circuitryactivates the notification emitter to indicate a direction of travel fora wearer of the SCL.
 11. The system of claim 8, wherein the optical dataincludes a notification corresponding to a mobile application, andwherein a color of the notification light corresponds with a particularcategory of mobile application.
 12. The system of claim 8, wherein theone or more optical emitters include light-emitting-diodes (“LEDs”). 13.The system of claim 8, wherein the optical emitters are configured foruse in luminaires.
 14. The system of claim 8, wherein the smart contactlens includes an outward facing emitter positioned to emit device data.15. A system comprising: one or more optical emitters that emit light; atransceiver coupled to receive input data from a data network andcoupled to selectively modulate the optical emitters to transmit opticaldata via the light, wherein selectively modulating the optical emittersis in response to the input data; and a smart contact lens (“SCL”)including: a photodetector positioned to receive the optical data;processing circuitry configured to initiate an action in response toreceiving the optical data from the photodetector; and a memory coupledto the processing circuitry, wherein the optical data is encrypted andthe memory stores a decryption key accessible to the processingcircuitry for decrypting the optical data.
 16. The system of claim 15further comprising: a mobile device for sending the input data to thedata network, wherein the mobile device is configured to encrypt theoptical data with an encryption key paired with the decryption keystored in the memory.
 17. A system comprising: one or more opticalemitters that emit light; a transceiver coupled to receive input datafrom a data network and coupled to selectively modulate the opticalemitters to transmit optical data via the light, wherein selectivelymodulating the optical emitters is in response to the input data; and asmart contact lens (“SCL”) including: a photodetector positioned toreceive the optical data; processing circuitry configured to initiate anaction in response to receiving the optical data from the photodetector;and a sensor coupled to the processing circuitry, wherein the processingcircuitry is configured to initiate a biometric measurement with thesensor in response to the optical data.
 18. The system of claim 17,wherein the SCL includes a notification emitter positioned to emitnotification light in an eyeward direction, wherein the processingcircuitry is coupled to activate the notification emitter in response tothe biometric measurement.
 19. A system comprising: one or more opticalemitters that emit light; a transceiver coupled to receive input datafrom a data network and coupled to selectively modulate the opticalemitters to transmit optical data via the light, wherein selectivelymodulating the optical emitters is in response to the input data; and asmart contact lens (“SCL”) including: a photodetector positioned toreceive the optical data; and processing circuitry configured toinitiate an action in response to receiving the optical data from thephotodetector, wherein the photodetector is a light-emitting-diode(“LED”) coupled to be selectively reversed biased by nodes of theprocessing circuitry, the LED further coupled to the nodes to beselectively driven as an outward facing emitter for emitting lens light,the processing circuitry coupled to modulate the lens light to generatelens data.
 20. The system of claim 19, wherein the LED is configured toemit infrared light as the lens light.
 21. The system of claim 19further comprising a second photodetector, wherein the transceiver iscoupled to receive the lens data from the second photodetector andcoupled to send the lens data to the data network.